/* * Copyright (c) 2022 * * This program is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License version 2 as * published by the Free Software Foundation; * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program; if not, write to the Free Software * Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA * * Author: Sebastien Deronne */ #include "ns3/boolean.h" #include "ns3/command-line.h" #include "ns3/config.h" #include "ns3/double.h" #include "ns3/eht-phy.h" #include "ns3/enum.h" #include "ns3/internet-stack-helper.h" #include "ns3/ipv4-address-helper.h" #include "ns3/ipv4-global-routing-helper.h" #include "ns3/log.h" #include "ns3/mobility-helper.h" #include "ns3/multi-model-spectrum-channel.h" #include "ns3/on-off-helper.h" #include "ns3/packet-sink-helper.h" #include "ns3/packet-sink.h" #include "ns3/rng-seed-manager.h" #include "ns3/spectrum-wifi-helper.h" #include "ns3/ssid.h" #include "ns3/string.h" #include "ns3/udp-client-server-helper.h" #include "ns3/uinteger.h" #include "ns3/wifi-acknowledgment.h" #include "ns3/yans-wifi-channel.h" #include "ns3/yans-wifi-helper.h" #include #include #include // This is a simple example in order to show how to configure an IEEE 802.11be Wi-Fi network. // // It outputs the UDP or TCP goodput for every EHT MCS value, which depends on the MCS value (0 to // 13), the channel width (20, 40, 80 or 160 MHz) and the guard interval (800ns, 1600ns or 3200ns). // The PHY bitrate is constant over all the simulation run. The user can also specify the distance // between the access point and the station: the larger the distance the smaller the goodput. // // The simulation assumes a configurable number of stations in an infrastructure network: // // STA AP // * * // | | // n1 n2 // // Packets in this simulation belong to BestEffort Access Class (AC_BE). // By selecting an acknowledgment sequence for DL MU PPDUs, it is possible to aggregate a // Round Robin scheduler to the AP, so that DL MU PPDUs are sent by the AP via DL OFDMA. using namespace ns3; NS_LOG_COMPONENT_DEFINE("eht-wifi-network"); /** * \param udp true if UDP is used, false if TCP is used * \param serverApp a container of server applications * \param payloadSize the size in bytes of the packets * \return the bytes received by each server application */ std::vector GetRxBytes(bool udp, const ApplicationContainer& serverApp, uint32_t payloadSize) { std::vector rxBytes(serverApp.GetN(), 0); if (udp) { for (uint32_t i = 0; i < serverApp.GetN(); i++) { rxBytes[i] = payloadSize * DynamicCast(serverApp.Get(i))->GetReceived(); } } else { for (uint32_t i = 0; i < serverApp.GetN(); i++) { rxBytes[i] = DynamicCast(serverApp.Get(i))->GetTotalRx(); } } return rxBytes; }; /** * Print average throughput over an intermediate time interval. * \param rxBytes a vector of the amount of bytes received by each server application * \param udp true if UDP is used, false if TCP is used * \param serverApp a container of server applications * \param payloadSize the size in bytes of the packets * \param tputInterval the duration of an intermediate time interval * \param simulationTime the simulation time in seconds */ void PrintIntermediateTput(std::vector& rxBytes, bool udp, const ApplicationContainer& serverApp, uint32_t payloadSize, Time tputInterval, double simulationTime) { auto newRxBytes = GetRxBytes(udp, serverApp, payloadSize); Time now = Simulator::Now(); std::cout << "[" << (now - tputInterval).As(Time::S) << " - " << now.As(Time::S) << "] Per-STA Throughput (Mbit/s):"; for (std::size_t i = 0; i < newRxBytes.size(); i++) { std::cout << "\t\t(" << i << ") " << (newRxBytes[i] - rxBytes[i]) * 8. / tputInterval.GetMicroSeconds(); // Mbit/s } std::cout << std::endl; rxBytes.swap(newRxBytes); if (now < Seconds(simulationTime) - NanoSeconds(1)) { Simulator::Schedule(Min(tputInterval, Seconds(simulationTime) - now - NanoSeconds(1)), &PrintIntermediateTput, rxBytes, udp, serverApp, payloadSize, tputInterval, simulationTime); } } int main(int argc, char* argv[]) { bool udp{true}; bool downlink{true}; bool useRts{false}; bool useExtendedBlockAck{false}; double simulationTime{10}; // seconds double distance{1.0}; // meters double frequency{5}; // whether the first link operates in the 2.4, 5 or 6 GHz double frequency2{0}; // whether the second link operates in the 2.4, 5 or 6 GHz (0 means no // second link exists) double frequency3{ 0}; // whether the third link operates in the 2.4, 5 or 6 GHz (0 means no third link exists) std::size_t nStations{1}; std::string dlAckSeqType{"NO-OFDMA"}; bool enableUlOfdma{false}; bool enableBsrp{false}; int mcs{-1}; // -1 indicates an unset value uint32_t payloadSize = 700; // must fit in the max TX duration when transmitting at MCS 0 over an RU of 26 tones Time tputInterval{0}; // interval for detailed throughput measurement double minExpectedThroughput{0}; double maxExpectedThroughput{0}; Time accessReqInterval{0}; CommandLine cmd(__FILE__); cmd.AddValue( "frequency", "Whether the first link operates in the 2.4, 5 or 6 GHz band (other values gets rejected)", frequency); cmd.AddValue( "frequency2", "Whether the second link operates in the 2.4, 5 or 6 GHz band (0 means the device has one " "link, otherwise the band must be different than first link and third link)", frequency2); cmd.AddValue( "frequency3", "Whether the third link operates in the 2.4, 5 or 6 GHz band (0 means the device has up to " "two links, otherwise the band must be different than first link and second link)", frequency3); cmd.AddValue("distance", "Distance in meters between the station and the access point", distance); cmd.AddValue("simulationTime", "Simulation time in seconds", simulationTime); cmd.AddValue("udp", "UDP if set to 1, TCP otherwise", udp); cmd.AddValue("downlink", "Generate downlink flows if set to 1, uplink flows otherwise", downlink); cmd.AddValue("useRts", "Enable/disable RTS/CTS", useRts); cmd.AddValue("useExtendedBlockAck", "Enable/disable use of extended BACK", useExtendedBlockAck); cmd.AddValue("nStations", "Number of non-AP HE stations", nStations); cmd.AddValue("dlAckType", "Ack sequence type for DL OFDMA (NO-OFDMA, ACK-SU-FORMAT, MU-BAR, AGGR-MU-BAR)", dlAckSeqType); cmd.AddValue("enableUlOfdma", "Enable UL OFDMA (useful if DL OFDMA is enabled and TCP is used)", enableUlOfdma); cmd.AddValue("enableBsrp", "Enable BSRP (useful if DL and UL OFDMA are enabled and TCP is used)", enableBsrp); cmd.AddValue( "muSchedAccessReqInterval", "Duration of the interval between two requests for channel access made by the MU scheduler", accessReqInterval); cmd.AddValue("mcs", "if set, limit testing to a specific MCS (0-11)", mcs); cmd.AddValue("payloadSize", "The application payload size in bytes", payloadSize); cmd.AddValue("tputInterval", "duration of intervals for throughput measurement", tputInterval); cmd.AddValue("minExpectedThroughput", "if set, simulation fails if the lowest throughput is below this value", minExpectedThroughput); cmd.AddValue("maxExpectedThroughput", "if set, simulation fails if the highest throughput is above this value", maxExpectedThroughput); cmd.Parse(argc, argv); if (useRts) { Config::SetDefault("ns3::WifiRemoteStationManager::RtsCtsThreshold", StringValue("0")); Config::SetDefault("ns3::WifiDefaultProtectionManager::EnableMuRts", BooleanValue(true)); } if (dlAckSeqType == "ACK-SU-FORMAT") { Config::SetDefault("ns3::WifiDefaultAckManager::DlMuAckSequenceType", EnumValue(WifiAcknowledgment::DL_MU_BAR_BA_SEQUENCE)); } else if (dlAckSeqType == "MU-BAR") { Config::SetDefault("ns3::WifiDefaultAckManager::DlMuAckSequenceType", EnumValue(WifiAcknowledgment::DL_MU_TF_MU_BAR)); } else if (dlAckSeqType == "AGGR-MU-BAR") { Config::SetDefault("ns3::WifiDefaultAckManager::DlMuAckSequenceType", EnumValue(WifiAcknowledgment::DL_MU_AGGREGATE_TF)); } else if (dlAckSeqType != "NO-OFDMA") { NS_ABORT_MSG("Invalid DL ack sequence type (must be NO-OFDMA, ACK-SU-FORMAT, MU-BAR or " "AGGR-MU-BAR)"); } double prevThroughput[12] = {0}; std::cout << "MCS value" << "\t\t" << "Channel width" << "\t\t" << "GI" << "\t\t\t" << "Throughput" << '\n'; int minMcs = 0; int maxMcs = 13; if (mcs >= 0 && mcs <= 13) { minMcs = mcs; maxMcs = mcs; } for (int mcs = minMcs; mcs <= maxMcs; mcs++) { uint8_t index = 0; double previous = 0; uint16_t maxChannelWidth = (frequency != 2.4 && frequency2 != 2.4 && frequency3 != 2.4) ? 160 : 40; for (int channelWidth = 20; channelWidth <= maxChannelWidth;) // MHz { for (int gi = 3200; gi >= 800;) // Nanoseconds { if (!udp) { Config::SetDefault("ns3::TcpSocket::SegmentSize", UintegerValue(payloadSize)); } NodeContainer wifiStaNodes; wifiStaNodes.Create(nStations); NodeContainer wifiApNode; wifiApNode.Create(1); NetDeviceContainer apDevice; NetDeviceContainer staDevices; WifiMacHelper mac; WifiHelper wifi; wifi.SetStandard(WIFI_STANDARD_80211be); std::array channelStr; uint8_t nLinks = 0; std::string dataModeStr = "EhtMcs" + std::to_string(mcs); std::string ctrlRateStr; uint64_t nonHtRefRateMbps = EhtPhy::GetNonHtReferenceRate(mcs) / 1e6; if (frequency2 == frequency || frequency3 == frequency || (frequency3 != 0 && frequency3 == frequency2)) { std::cout << "Frequency values must be unique!" << std::endl; return 0; } for (auto freq : {frequency, frequency2, frequency3}) { if (nLinks > 0 && freq == 0) { break; } channelStr[nLinks] = "{0, " + std::to_string(channelWidth) + ", "; if (freq == 6) { channelStr[nLinks] += "BAND_6GHZ, 0}"; Config::SetDefault("ns3::LogDistancePropagationLossModel::ReferenceLoss", DoubleValue(48)); wifi.SetRemoteStationManager(nLinks, "ns3::ConstantRateWifiManager", "DataMode", StringValue(dataModeStr), "ControlMode", StringValue(dataModeStr)); } else if (freq == 5) { channelStr[nLinks] += "BAND_5GHZ, 0}"; ctrlRateStr = "OfdmRate" + std::to_string(nonHtRefRateMbps) + "Mbps"; wifi.SetRemoteStationManager(nLinks, "ns3::ConstantRateWifiManager", "DataMode", StringValue(dataModeStr), "ControlMode", StringValue(ctrlRateStr)); } else if (freq == 2.4) { channelStr[nLinks] += "BAND_2_4GHZ, 0}"; Config::SetDefault("ns3::LogDistancePropagationLossModel::ReferenceLoss", DoubleValue(40)); ctrlRateStr = "ErpOfdmRate" + std::to_string(nonHtRefRateMbps) + "Mbps"; wifi.SetRemoteStationManager(nLinks, "ns3::ConstantRateWifiManager", "DataMode", StringValue(dataModeStr), "ControlMode", StringValue(ctrlRateStr)); } else { std::cout << "Wrong frequency value!" << std::endl; return 0; } nLinks++; } Ssid ssid = Ssid("ns3-80211be"); /* * SingleModelSpectrumChannel cannot be used with 802.11be because two * spectrum models are required: one with 78.125 kHz bands for HE PPDUs * and one with 312.5 kHz bands for, e.g., non-HT PPDUs (for more details, * see issue #408 (CLOSED)) */ Ptr spectrumChannel = CreateObject(); Ptr lossModel = CreateObject(); spectrumChannel->AddPropagationLossModel(lossModel); SpectrumWifiPhyHelper phy(nLinks); phy.SetPcapDataLinkType(WifiPhyHelper::DLT_IEEE802_11_RADIO); phy.SetChannel(spectrumChannel); mac.SetType("ns3::StaWifiMac", "Ssid", SsidValue(ssid)); for (uint8_t linkId = 0; linkId < nLinks; linkId++) { phy.Set(linkId, "ChannelSettings", StringValue(channelStr[linkId])); } staDevices = wifi.Install(phy, mac, wifiStaNodes); if (dlAckSeqType != "NO-OFDMA") { mac.SetMultiUserScheduler("ns3::RrMultiUserScheduler", "EnableUlOfdma", BooleanValue(enableUlOfdma), "EnableBsrp", BooleanValue(enableBsrp), "AccessReqInterval", TimeValue(accessReqInterval)); } mac.SetType("ns3::ApWifiMac", "EnableBeaconJitter", BooleanValue(false), "Ssid", SsidValue(ssid)); apDevice = wifi.Install(phy, mac, wifiApNode); RngSeedManager::SetSeed(1); RngSeedManager::SetRun(1); int64_t streamNumber = 100; streamNumber += wifi.AssignStreams(apDevice, streamNumber); streamNumber += wifi.AssignStreams(staDevices, streamNumber); // Set guard interval and MPDU buffer size Config::Set( "/NodeList/*/DeviceList/*/$ns3::WifiNetDevice/HeConfiguration/GuardInterval", TimeValue(NanoSeconds(gi))); Config::Set( "/NodeList/*/DeviceList/*/$ns3::WifiNetDevice/HeConfiguration/MpduBufferSize", UintegerValue(useExtendedBlockAck ? 256 : 64)); // mobility. MobilityHelper mobility; Ptr positionAlloc = CreateObject(); positionAlloc->Add(Vector(0.0, 0.0, 0.0)); positionAlloc->Add(Vector(distance, 0.0, 0.0)); mobility.SetPositionAllocator(positionAlloc); mobility.SetMobilityModel("ns3::ConstantPositionMobilityModel"); mobility.Install(wifiApNode); mobility.Install(wifiStaNodes); /* Internet stack*/ InternetStackHelper stack; stack.Install(wifiApNode); stack.Install(wifiStaNodes); Ipv4AddressHelper address; address.SetBase("192.168.1.0", "255.255.255.0"); Ipv4InterfaceContainer staNodeInterfaces; Ipv4InterfaceContainer apNodeInterface; staNodeInterfaces = address.Assign(staDevices); apNodeInterface = address.Assign(apDevice); /* Setting applications */ ApplicationContainer serverApp; auto serverNodes = downlink ? std::ref(wifiStaNodes) : std::ref(wifiApNode); Ipv4InterfaceContainer serverInterfaces; NodeContainer clientNodes; for (std::size_t i = 0; i < nStations; i++) { serverInterfaces.Add(downlink ? staNodeInterfaces.Get(i) : apNodeInterface.Get(0)); clientNodes.Add(downlink ? wifiApNode.Get(0) : wifiStaNodes.Get(i)); } if (udp) { // UDP flow uint16_t port = 9; UdpServerHelper server(port); serverApp = server.Install(serverNodes.get()); serverApp.Start(Seconds(0.0)); serverApp.Stop(Seconds(simulationTime + 1)); for (std::size_t i = 0; i < nStations; i++) { UdpClientHelper client(serverInterfaces.GetAddress(i), port); client.SetAttribute("MaxPackets", UintegerValue(4294967295U)); client.SetAttribute("Interval", TimeValue(Time("0.00001"))); // packets/s client.SetAttribute("PacketSize", UintegerValue(payloadSize)); ApplicationContainer clientApp = client.Install(clientNodes.Get(i)); clientApp.Start(Seconds(1.0)); clientApp.Stop(Seconds(simulationTime + 1)); } } else { // TCP flow uint16_t port = 50000; Address localAddress(InetSocketAddress(Ipv4Address::GetAny(), port)); PacketSinkHelper packetSinkHelper("ns3::TcpSocketFactory", localAddress); serverApp = packetSinkHelper.Install(serverNodes.get()); serverApp.Start(Seconds(0.0)); serverApp.Stop(Seconds(simulationTime + 1)); for (std::size_t i = 0; i < nStations; i++) { OnOffHelper onoff("ns3::TcpSocketFactory", Ipv4Address::GetAny()); onoff.SetAttribute("OnTime", StringValue("ns3::ConstantRandomVariable[Constant=1]")); onoff.SetAttribute("OffTime", StringValue("ns3::ConstantRandomVariable[Constant=0]")); onoff.SetAttribute("PacketSize", UintegerValue(payloadSize)); onoff.SetAttribute("DataRate", DataRateValue(1000000000)); // bit/s AddressValue remoteAddress( InetSocketAddress(serverInterfaces.GetAddress(i), port)); onoff.SetAttribute("Remote", remoteAddress); ApplicationContainer clientApp = onoff.Install(clientNodes.Get(i)); clientApp.Start(Seconds(1.0)); clientApp.Stop(Seconds(simulationTime + 1)); } } // cumulative number of bytes received by each server application std::vector cumulRxBytes(nStations, 0); if (tputInterval.IsStrictlyPositive()) { Simulator::Schedule(Seconds(1) + tputInterval, &PrintIntermediateTput, cumulRxBytes, udp, serverApp, payloadSize, tputInterval, simulationTime + 1); } Simulator::Schedule(Seconds(0), &Ipv4GlobalRoutingHelper::PopulateRoutingTables); Simulator::Stop(Seconds(simulationTime + 1)); Simulator::Run(); // When multiple stations are used, there are chances that association requests // collide and hence the throughput may be lower than expected. Therefore, we relax // the check that the throughput cannot decrease by introducing a scaling factor (or // tolerance) double tolerance = 0.10; cumulRxBytes = GetRxBytes(udp, serverApp, payloadSize); uint64_t rxBytes = std::accumulate(cumulRxBytes.cbegin(), cumulRxBytes.cend(), 0); double throughput = (rxBytes * 8) / (simulationTime * 1000000.0); // Mbit/s Simulator::Destroy(); std::cout << mcs << "\t\t\t" << channelWidth << " MHz\t\t\t" << gi << " ns\t\t\t" << throughput << " Mbit/s" << std::endl; // test first element if (mcs == 0 && channelWidth == 20 && gi == 3200) { if (throughput * (1 + tolerance) < minExpectedThroughput) { NS_LOG_ERROR("Obtained throughput " << throughput << " is not expected!"); exit(1); } } // test last element if (mcs == 11 && channelWidth == 160 && gi == 800) { if (maxExpectedThroughput > 0 && throughput > maxExpectedThroughput * (1 + tolerance)) { NS_LOG_ERROR("Obtained throughput " << throughput << " is not expected!"); exit(1); } } // test previous throughput is smaller (for the same mcs) if (throughput * (1 + tolerance) > previous) { previous = throughput; } else if (throughput > 0) { NS_LOG_ERROR("Obtained throughput " << throughput << " is not expected!"); exit(1); } // test previous throughput is smaller (for the same channel width and GI) if (throughput * (1 + tolerance) > prevThroughput[index]) { prevThroughput[index] = throughput; } else if (throughput > 0) { NS_LOG_ERROR("Obtained throughput " << throughput << " is not expected!"); exit(1); } index++; gi /= 2; } channelWidth *= 2; } } return 0; }